JavaScript is disabled for your browser. Some features of this site may not work without it.
| dc.contributor.author | Ків, Арнольд Юхимович | |
| dc.contributor.author | Соловйов, Володимир Миколайович | |
| dc.contributor.author | Tomilin, Sergey A. | |
| dc.date.accessioned | 2017-07-09T11:44:03Z | |
| dc.date.available | 2017-07-09T11:44:03Z | |
| dc.date.issued | 2001 | |
| dc.identifier.citation | Kiv A. E. Formation of Si precipitates іn neutron irradiated Al / A. E. Kiv, V. N. Solovyov, S. A. Tomilin // Комп’ютерне моделювання та інформаційні технології в науці, економіці та освіті : збірник наукових праць. В 2-х томах. – Кривий Ріг, 2001. – Т. 1. – С. 119-126. | uk |
| dc.identifier.uri | http://elibrary.kdpu.edu.ua/handle/0564/1027 | |
| dc.identifier.uri | https://doi.org/10.31812/0564/1027 | |
| dc.description | 1. K. Farrell. Response of Aluminum and its Alloys to Exposure in the High Flux Isotope Reactor. Dimensional Stability and Mechanical Behaviour of Irradiated Metals and Allows, (1983) British Nucl. Energy Soc. London. A. Munitz. Neutron Irradiation Effects on Commercial Purity Type A5 Aluminum. Journ. Nucl. Materials, (1989) 165, pp. 305-312. A. Munitz, A. Shtcchman, C. Cotler, M. Talianker, S. Dahan. Mechanical Properties and Microstructure of Neutron Irradiated Cold Worked All-6063 Alloy. Joum. Nucl. Materials, (1998) 252, pp.79-88. 2. K. Farrell, J.O. Stieglcr, R.E. Gehlbash. Transmutation-Produces Silicon Precipitates in Irradiated Aluminum. Metallography (1970) 3, pp. 275-384. 3. N.M. Packan. Fluence and Flux Dependence of Void Formation in Pure Aluminum. Journal Nucl. Materials (1971) 40, pp. 1-16 4. A.J. Ardell. Precipitation Hardening Metallurgical Trans. (1985) I6A, pp. 2132-2165. 5. B.Ya. Lubov. Diffusion Kinetics of Macroscopic Defects. In “Materials of Intern. School on the Theory of Defects in Crystals” (1966), Tbilisi, pp. 209-235 (in Russian). 6. D.E. Ellis, S. Dorfman, D. Fuks, R. Evenhaim, K.C. Mundim. Embedded cluster and Superccll Study of the Structure of the Interstitial Cu-C Solid Solutions. Journal Quantum Chem.(1998) 70, p. 1085 7. A.M. Kosevich. Elastic and Diffusion Interaction of Dislocations and Point Defects. Advances of Physical Sciences (1964) 84,p. 579 (in Russian) 8. R.A. Johnson, E. Brown. Energies of Interstitial Atoms Formation and Migration in Metals. Phys. Rev. 127 (1962), p.446. 9. S.I. Pekar. Investigations on the Electronic Theory of Crystals (1951) Moscow (in Russian) 10. V.L. Indcnbom, A.E. Kiv. Radiation-Stimulated Diffusion in "Radiation physics of Semiconductors and Related Materials" (1984) Tbilisi, pp. 111-120 11. R.M. Barrer. Diffusion in and through Solids (1941) Cambridge | |
| dc.description.abstract | Transmutation reactions are the unique way to get a large concentration of Silicon atoms in Aluminum lattice, and just in substitutional positions. Appearing Silicon atoms in Aluminum lattice instead of Aluminum atoms leads to arising of mechanical stresses. This factor is the keystone of the model, which allows to explain the main peculiarities of Si precipitate creation in Aluminum irradiated by thermal neutrons. First, we shall describe the qualitative peculiarities of the model. Then we shall perform some quantitative estimates. At last the model will be discussed and compared with experimental data. | uk |
| dc.language.iso | en | uk |
| dc.publisher | Видавничий відділ КДПУ | uk |
| dc.subject | Silicon precipitates | uk |
| dc.subject | diamond-like Silicon cluster | uk |
| dc.title | Formation of Si precipitates іn neutron irradiated Al | uk |
| dc.type | Article | uk |
